Heat Stress Responses in Cultured Plant Cells

Wu, Min-Tze; Wallner, Stephen J.

doi:10.1104/pp.72.3.817

Cited by 52 publications

(18 citation statements)

References 15 publications

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“…Knowledge initial study (15). The culture medium and most methods (culture maintenance, growth conditions and measurement, heat stress treatment, and viability tests) were as described previously (15 (13,14).…”

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Heat Stress Responses in Cultured Plant Cells

Wu¹,

Wallner²,

Waddell³

1984

Plant Physiol.

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The pipetting ofpear (Pyrus communis cv Bartlett) suspension cultures was followed by a substantial but transient decrease in heat sensitivity. During a culture cycle, pear cells were most sensitive to heat at day 3, which coincided with the period of most active cell division. To minimize serious artifacts, the influence of culture handling and age on parameters such as heat sensitivity must be standardized.In the study of complex phenomena such as temperature response, the convenience, simplicity, and uniformity of cell cultures make them valuable experimental systems. Although effects ofheat stress on photosynthesis are critical to whole plants, the absence of chloroplasts in simple cell cultures may further facilitate close examination of other metabolic responses. In considering tissue cultures as model systems, it is important to note that certain aspects of cultured cell response to heat are similar to those of intact plant tissues. Heat stress disrupts polysomes in cells of intact pear fruit (10) and in cultured pear fruit cells (Romani, personal communication). In both intact organs and tissue cultures, heat shock induces acclimation (8,12) and the synthesis of heat-shock proteins (1, 7). However, it is clear that the isolation and culture of plant cells alters physiological characteristics which may influence high temperature response. For example, batch-propagated suspension cultures are characterized by stages ofrelatively high mitotic activity (5). This is relevant to the study of heat stress because certain dividing cells are especially susceptible to heat injury (9, 1 1). Therefore, it is necessary to consider the relationship of culture age to heat sensitivity. Another inherent feature of tissue culture systems is the routine handling and manipulation involved in the transfer and treatment ofcells. Tissue handling has been shown to induce subtle but substantial metabolic changes (13,14), some ofwhich could influence heat tolerance.In this paper, we describe effects of suspension culture age and handling of the heat tolerance of pear cells. (13,14). Our procedure (15) involved pipetting aliquots to test tubes for imposition of heat stress. We found that handling (transfer by pipette) influenced heat sensitivity (Fig. 1)

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“…The culture medium and most methods (culture maintenance, growth conditions and measurement, heat stress treatment, and viability tests) were as described previously (15 (13,14). Our procedure (15) involved pipetting aliquots to test tubes for imposition of heat stress. We found that handling (transfer by pipette) influenced heat sensitivity (Fig.…”

mentioning

confidence: 99%

Heat Stress Responses in Cultured Plant Cells

Wu¹,

Wallner²,

Waddell³

1984

Plant Physiol.

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“…In the experiments for Figure 2, zero time measurements could not be obtained. However, without the handling involved in HS treatment, 22°C-grown cells showed less than 15% survival of a 43°C, 20-min stress (13). Heat tolerance was fully maintained for 2 d at 22°C and then began to gradually decline (Fig.…”

Section: Methodsmentioning

confidence: 98%

“…All experiments were conducted with suspension-cultured cells of pear (Pyrus communis cv Bartlett) which were used in our previous studies (13,14). The culture medium and most methods (culture maintenance, growth conditions and measurement, heat stress treatment, and viability tests) were as described before (13).…”

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Heat Stress Responses in Cultured Plant Cells

Wu¹,

Wallner²

1984

Plant Physiol.

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Using cultured pear (Pyrus communis cv Bartlett) cells, heat tolerance induced by heat shock was compared to that developed during growth at high temperature. After growth at 22°C, cells exposed to 38°C for 20 minutes (heat shock) showed maximum increased tolerance within 6 hours. Cells grown at 30°C developed maximum heat tolerance after 5 to 6 days; this maximum was well below that induced by heat shock. Heat shock-induced tolerance was fully retained at 22°C for 2 days and was only partly lost after 4 days. However, pear cells acclimated at 30°C lost all acquired heat tolerance I to 2 days after transfer to 22°C. In addition, cells which had been heat-acclimated by growth at 30°C showed an additional increase in heat tolerance in response to 39°C heat shock. The most striking difference between heat shock and high growth temperature effects on heat tolerance was revealed when tolerance was determined using viability tests based on different cell functions. Growth at 30°C produced a general hardening, i.e. increased heat tolerance was observed with all three viability tests. In contrast, significantly increased tolerance of heat-shocked cells was observed only with the culture regrowth test. The two types of treatment evoke different mechanisms of heat acclimation.are constants). If so, then heat acclimation induced by brief HS and that induced by prolonged but more moderate heat (e.g. 30C) would have similar mechanisms. However, results presented in this paper indicate that HS and prolonged exposure to 30°C increase the heat tolerance of pear cells in clearly different ways. MATERIALS AND METHODSAll experiments were conducted with suspension-cultured cells of pear (Pyrus communis cv Bartlett) which were used in our previous studies (13,14). The culture medium and most methods (culture maintenance, growth conditions and measurement, heat stress treatment, and viability tests) were as described before (13). All stock cultures and experimental controls were grown at 22C.Heat shock was administered to cells from 7-d-old suspension cultures using 5-ml aliquots in 1 x 10 cm test tubes. Heat treatment was accomplished in a water bath at the HS temperature; temperature equilibration in the 5-ml aliquots occurred within 3 min. The HS treatments lasted 20 min after which six of the 5-ml heat-shocked cell suspensions were transferred to empty, sterile 125-ml Erlenmeyer flasks and maintained at 22°C with shaking. Non-heat-shocked controls were subjected to the same sample handling procedures.Heat shock, i.e. brief exposure to supraoptimal temperature, alters gene expression and leads to increased heat tolerance in a wide range of organisms (10) 2Abbreviations: HS, heat shock; TTC, triphenyl-tetrazolium chloride. RESULTS AND DISCUSSIONHS-Induced Tolerance. Pear cells exposed to 38C for 20 min and then incubated for 24 h at 22C showed greatly increased tolerance of a subsequent heat stress treatment (Fig. 1) (8) and soybean seedlings (7). Schroeder (11) showed that heat tolerance was induced in avocado tissue cultu...

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